// SPDX-FileCopyrightText: Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen
// SPDX-FileCopyrightText: Copyright (c) 2000 - 2009, Lawrence Livermore National Security, LLC
// SPDX-License-Identifier: BSD-3-Clause

#include "vtkTecplotReader.h"

#include "vtkCallbackCommand.h"
#include "vtkCellArray.h"
#include "vtkCellData.h"
#include "vtkCompositeDataPipeline.h"
#include "vtkDataArraySelection.h"
#include "vtkFloatArray.h"
#include "vtkIdTypeArray.h"
#include "vtkInformation.h"
#include "vtkInformationVector.h"
#include "vtkMath.h"
#include "vtkMultiBlockDataSet.h"
#include "vtkObjectFactory.h"
#include "vtkPointData.h"
#include "vtkPoints.h"
#include "vtkStructuredGrid.h"
#include "vtkUnsignedCharArray.h"
#include "vtkUnstructuredGrid.h"

#include "vtk_zlib.h"
#include <vtksys/SystemTools.hxx>

#include <cctype> // for isspace(), isalnum()

VTK_ABI_NAMESPACE_BEGIN
vtkStandardNewMacro(vtkTecplotReader);

// ============================================================================
class FileStreamReader
{
public:
  FileStreamReader();
  ~FileStreamReader();

  bool open(const char* fileName);
  bool is_open() const { return Open; }
  bool eof() const { return Eof; }

  void rewind();
  void close();
  int get();
  bool operator!() const;

protected:
  bool Open;
  bool Eof;
  static const int BUFF_SIZE = 2048;
  char buff[BUFF_SIZE];
  int Pos;
  int BuffEnd;
  gzFile file;
  std::string FileName;
};

//------------------------------------------------------------------------------
FileStreamReader::FileStreamReader()
  : Open(false)
  , Eof(true)
  , Pos(BUFF_SIZE)
  , BuffEnd(BUFF_SIZE)
{
}

//------------------------------------------------------------------------------
FileStreamReader::~FileStreamReader()
{
  this->close();
}

//------------------------------------------------------------------------------
bool FileStreamReader::open(const char* fileName)
{
  if (!this->Open)
  {
    this->FileName = std::string(fileName);
    // zlib handles both compressed and uncompressed file
    // we just have peak into the file and see if it has the magic
    // flags or not
    unsigned char magic[2];
    FILE* ff = vtksys::SystemTools::Fopen(fileName, "rb");
    size_t count = fread(magic, 1, 2, ff);
    fclose(ff);

    // only continue if fread succeeded
    if (count == 2)
    {
      const char* mode = (magic[0] == 0x1f && magic[1] == 0x8b) ? "rb" : "r";
      this->file = gzopen(fileName, mode);

      this->Eof = (this->file == nullptr);
      this->Open = (this->file != nullptr);
      this->Pos = BUFF_SIZE;
    }
  }
  return this->Open;
}
//------------------------------------------------------------------------------
int FileStreamReader::get()
{
  if (!this->is_open() || this->eof())
  {
    return this->eof();
  }

  // when reading uncompressed data, zlib will return if it hits
  // and eol character

  if (this->Pos >= this->BuffEnd)
  {
    this->Pos = 0;
    // read the first buffer
    this->BuffEnd = gzread(this->file, this->buff, FileStreamReader::BUFF_SIZE);
    // assign EOF to what gzread returned
    this->Eof = (this->BuffEnd <= 0);
    if (this->Eof)
    {
      return this->Eof;
    }
  }
  return this->buff[this->Pos++];
}

//------------------------------------------------------------------------------
void FileStreamReader::rewind()
{
  if (this->Open)
  {
    // we don't want to use gzrewind as it rewinds to not the start of the
    // file, but to start of the data in the file, meaning we are past any
    // comments or headers.
    std::string fn = this->FileName;
    this->close();
    this->open(fn.c_str());
  }
}

//------------------------------------------------------------------------------
void FileStreamReader::close()
{
  if (this->Open)
  {
    this->Open = false;
    this->Eof = false;
    this->Pos = FileStreamReader::BUFF_SIZE;
    this->BuffEnd = FileStreamReader::BUFF_SIZE;
    this->FileName = std::string();

    gzclose(this->file);
  }
}

//------------------------------------------------------------------------------
bool FileStreamReader::operator!() const
{
  return this->Eof;
}

// ==========================================================================//
class vtkTecplotReaderInternal
{
public:
  vtkTecplotReaderInternal() { this->Init(); }
  ~vtkTecplotReaderInternal() { this->Init(); }

  int XIdInList;
  int YIdInList;
  int ZIdInList;
  int Completed;
  int GeometryDim;
  int TopologyDim;
  char TheNextChar;
  bool NextCharEOF;
  bool NextCharEOL;
  bool NextCharValid;
  bool TokenIsString;
  bool IsCompressed;
  FileStreamReader ASCIIStream;
  std::string TokenBackup;

  void Init()
  {
    this->Completed = 0;
    this->XIdInList = -1;
    this->YIdInList = -1;
    this->ZIdInList = -1;

    this->TopologyDim = 0;
    this->GeometryDim = 1;
    this->TheNextChar = '\0';
    this->TokenBackup = "";
    this->NextCharEOF = false;
    this->NextCharEOL = false;
    this->NextCharValid = false;
    this->TokenIsString = false;
    this->IsCompressed = false;
  }

  // This functions obtains the next token from the ASCII stream.
  // Note that it is assumed that the ASCII stream is ready and no
  // reading error occurs.
  std::string GetNextToken()
  {
    // this is where we take a one-token lookahead
    if (!this->TokenBackup.empty())
    {
      std::string retval = this->TokenBackup;
      this->TokenBackup = "";
      return retval;
    }

    // oops!  we hit EOF and someone still wants more.
    if (this->NextCharEOF)
    {
      return "";
    }

    this->NextCharEOL = false;
    this->TokenIsString = false;

    std::string retval;
    if (!this->NextCharValid)
    {
      this->TheNextChar = this->ASCIIStream.get();
      this->NextCharValid = true;

      if (!this->ASCIIStream)
      {
        this->NextCharEOF = true;
      }
    }

    // if the token is a comment token, skip the entire line
    if (!this->NextCharEOF && this->TheNextChar == '#')
    {
      while ((!this->NextCharEOF) && (this->TheNextChar != '\n') && (this->TheNextChar != '\r'))
      {
        this->TheNextChar = this->ASCIIStream.get();
        if (this->TheNextChar == '\n' || this->TheNextChar == '\r')
        {
          this->NextCharEOL = true;
        }
      }
    }

    // skip inter-token whitespace
    while (!this->NextCharEOF &&
      (this->TheNextChar == ' ' || this->TheNextChar == '\n' || this->TheNextChar == '\r' ||
        this->TheNextChar == '\t' || this->TheNextChar == '=' || this->TheNextChar == '(' ||
        this->TheNextChar == ')' || this->TheNextChar == ','))
    {
      if (this->TheNextChar == '\n' || this->TheNextChar == '\r')
      {
        this->NextCharEOL = true;
      }

      this->TheNextChar = this->ASCIIStream.get();
      if (!this->ASCIIStream)
      {
        this->NextCharEOF = true;
      }

      // Ignore blank lines since they don't return a token
      if (this->NextCharEOL)
      {
        return this->GetNextToken();
      }
    }

    if (this->TheNextChar == '\"')
    {
      this->TokenIsString = true;
      this->TheNextChar = this->ASCIIStream.get();
      if (!this->ASCIIStream)
      {
        this->NextCharEOF = true;
      }

      while (!this->NextCharEOF && this->TheNextChar != '\"')
      {
        retval += this->TheNextChar;
        this->TheNextChar = this->ASCIIStream.get();

        if (!this->ASCIIStream)
        {
          this->NextCharEOF = true;
        }
      }

      this->TheNextChar = this->ASCIIStream.get();
      if (!this->ASCIIStream)
      {
        this->NextCharEOF = true;
      }
    }
    else
    {
      // handle a normal token
      while (!this->NextCharEOF &&
        (this->TheNextChar != ' ' && this->TheNextChar != '\n' && this->TheNextChar != '\r' &&
          this->TheNextChar != '\t' && this->TheNextChar != '=' && this->TheNextChar != '(' &&
          this->TheNextChar != ')' && this->TheNextChar != ','))
      {
        if (this->TheNextChar >= 'a' && this->TheNextChar <= 'z')
        {
          this->TheNextChar += (int('A') - int('a'));
        }

        retval += this->TheNextChar;
        this->TheNextChar = this->ASCIIStream.get();

        if (!this->ASCIIStream)
        {
          this->NextCharEOF = true;
        }
      }
    }

    // skip whitespace to EOL
    while (!this->NextCharEOF &&
      (this->TheNextChar == ' ' || this->TheNextChar == '\n' || this->TheNextChar == '\r' ||
        this->TheNextChar == '\t' || this->TheNextChar == '=' || this->TheNextChar == '(' ||
        this->TheNextChar == ')' || this->TheNextChar == ','))
    {
      if (this->TheNextChar == '\n' || this->TheNextChar == '\r')
      {
        this->NextCharEOL = true;
      }

      this->TheNextChar = this->ASCIIStream.get();
      if (!this->ASCIIStream)
      {
        this->NextCharEOF = true;
      }

      if (this->NextCharEOL)
      {
        break;
      }
    }
    return retval;
  }

private:
  vtkTecplotReaderInternal(const vtkTecplotReaderInternal&) = delete;
  void operator=(const vtkTecplotReaderInternal&) = delete;
};
// ==========================================================================//

//------------------------------------------------------------------------------
//                         Supporting Functions (begin)
//------------------------------------------------------------------------------

//------------------------------------------------------------------------------
static int GetCoord(const std::string& theToken)
{
  if (theToken == "X" || theToken == "x" || theToken == "I" || theToken == "CoordinateX")
  {
    return 0;
  }

  if (theToken == "Y" || theToken == "y" || theToken == "J" || theToken == "CoordinateY")
  {
    return 1;
  }

  if (theToken == "Z" || theToken == "z" || theToken == "K" || theToken == "CoordinateZ")
  {
    return 2;
  }

  return -1;
}

//------------------------------------------------------------------------------
static int GuessCoord(const std::string& theToken)
{
  int guessVal = GetCoord(theToken);

  if (theToken.length() >= 3)
  {
    // do match: "x[m]" or "x (m)", etc. don't match: "x velocity"
    if ((!isspace(theToken[1]) && !isalnum(theToken[1])) ||
      (isspace(theToken[1] && !isalnum(theToken[2]))))
    {
      guessVal = GetCoord(theToken.substr(0, 1));
    }
  }

  return guessVal;
}

//------------------------------------------------------------------------------
static std::string SimplifyWhitespace(const std::string& s)
{
  int headIndx = 0;
  int tailIndx = int(s.length()) - 1;

  while (headIndx < tailIndx && (s[headIndx] == ' ' || s[headIndx] == '\t'))
  {
    headIndx++;
  }

  while (tailIndx > headIndx && (s[tailIndx] == ' ' || s[tailIndx] == '\t'))
  {
    tailIndx--;
  }

  return s.substr(headIndx, tailIndx - headIndx + 1);
}

//------------------------------------------------------------------------------
//                         Supporting Functions ( end )
//------------------------------------------------------------------------------

//------------------------------------------------------------------------------
vtkTecplotReader::vtkTecplotReader()
{
  this->SelectionObserver = vtkCallbackCommand::New();
  this->SelectionObserver->SetClientData(this);
  this->SelectionObserver->SetCallback(&vtkTecplotReader::SelectionModifiedCallback);

  this->DataArraySelection = vtkDataArraySelection::New();
  this->DataArraySelection->AddObserver(vtkCommand::ModifiedEvent, this->SelectionObserver);

  this->FileName = nullptr;
  this->Internal = new vtkTecplotReaderInternal;
  this->SetNumberOfInputPorts(0);

  this->Init();
}

//------------------------------------------------------------------------------
vtkTecplotReader::~vtkTecplotReader()
{
  this->Init();

  delete[] this->FileName;

  delete this->Internal;
  this->Internal = nullptr;

  this->DataArraySelection->RemoveAllArrays();
  this->DataArraySelection->RemoveObserver(this->SelectionObserver);
  this->DataArraySelection->Delete();
  this->DataArraySelection = nullptr;

  this->SelectionObserver->SetClientData(nullptr);
  this->SelectionObserver->SetCallback(nullptr);
  this->SelectionObserver->Delete();
  this->SelectionObserver = nullptr;
}

//------------------------------------------------------------------------------
void vtkTecplotReader::Init()
{
  // do NOT address this->FileName in this function !!!

  this->DataTitle = "";
  this->NumberOfVariables = 0;
  this->CellBased.clear();
  this->ZoneNames.clear();
  this->Variables.clear();

  this->Internal->Init();
}

//------------------------------------------------------------------------------
void vtkTecplotReader::SetFileName(const char* fileName)
{
  if (fileName && strcmp(fileName, "") != 0 &&
    ((this->FileName == nullptr) || strcmp(fileName, this->FileName) != 0))
  {
    delete[] this->FileName;
    this->FileName = new char[strlen(fileName) + 1];
    strcpy(this->FileName, fileName);
    this->FileName[strlen(fileName)] = '\0';

    this->Modified();
    this->Internal->Completed = 0;
  }
}

//------------------------------------------------------------------------------
void vtkTecplotReader::SelectionModifiedCallback(vtkObject*, unsigned long, void* tpReader, void*)
{
  static_cast<vtkTecplotReader*>(tpReader)->Modified();
}

//------------------------------------------------------------------------------
int vtkTecplotReader::FillOutputPortInformation(int vtkNotUsed(port), vtkInformation* info)
{
  info->Set(vtkDataObject::DATA_TYPE_NAME(), "vtkMultiBlockDataSet");
  return 1;
}

//------------------------------------------------------------------------------
int vtkTecplotReader::RequestInformation(
  vtkInformation* request, vtkInformationVector** inputVector, vtkInformationVector* outputVector)
{
  if (!this->Superclass::RequestInformation(request, inputVector, outputVector))
  {
    return 0;
  }

  this->GetDataArraysList();

  return 1;
}

//------------------------------------------------------------------------------
int vtkTecplotReader::RequestData(vtkInformation* vtkNotUsed(request),
  vtkInformationVector** vtkNotUsed(inputVector), vtkInformationVector* outputVector)
{
  vtkInformation* outInf = outputVector->GetInformationObject(0);
  vtkMultiBlockDataSet* output =
    vtkMultiBlockDataSet::SafeDownCast(outInf->Get(vtkDataObject::DATA_OBJECT()));

  this->Internal->Completed = 0;
  this->ReadFile(output);
  outInf = nullptr;
  output = nullptr;

  return 1;
}

//------------------------------------------------------------------------------
const char* vtkTecplotReader::GetDataTitle()
{
  return this->DataTitle.c_str();
}

//------------------------------------------------------------------------------
int vtkTecplotReader::GetNumberOfBlocks()
{
  return int(this->ZoneNames.size());
}

//------------------------------------------------------------------------------
const char* vtkTecplotReader::GetBlockName(int blockIdx)
{
  if (blockIdx < 0 || blockIdx >= int(this->ZoneNames.size()))
  {
    return nullptr;
  }

  return this->ZoneNames[blockIdx].c_str();
}

//------------------------------------------------------------------------------
int vtkTecplotReader::GetNumberOfDataAttributes()
{
  return this->NumberOfVariables - (!(!(this->Internal->XIdInList + 1))) -
    (!(!(this->Internal->YIdInList + 1))) - (!(!(this->Internal->ZIdInList + 1)));
}

//------------------------------------------------------------------------------
const char* vtkTecplotReader::GetDataAttributeName(int attrIndx)
{
  if (attrIndx < 0 && attrIndx >= this->GetNumberOfDataAttributes())
  {
    return nullptr;
  }

  return this->Variables[attrIndx + this->Variables.size() - this->GetNumberOfDataAttributes()]
    .c_str();
}

//------------------------------------------------------------------------------
int vtkTecplotReader::IsDataAttributeCellBased(int attrIndx)
{
  int cellBasd = -1;
  if (attrIndx >= 0 && attrIndx < this->GetNumberOfDataAttributes())
  {
    // the if-statement ensures that this->CellBased has been ready
    cellBasd =
      this->CellBased[attrIndx + this->CellBased.size() - this->GetNumberOfDataAttributes()];
  }

  return cellBasd;
}

//------------------------------------------------------------------------------
int vtkTecplotReader::IsDataAttributeCellBased(const char* attrName)
{
  int cellBased = -1;
  int varIndex = -1;

  if (attrName)
  {
    for (unsigned int i = 0; i < this->Variables.size(); i++)
    {
      if (this->Variables[i] == attrName)
      {
        varIndex = i;
        break;
      }
    }

    cellBased = (varIndex == -1) ? -1 : this->CellBased[varIndex];
  }

  return cellBased;
}

//------------------------------------------------------------------------------
int vtkTecplotReader::GetNumberOfDataArrays()
{
  return this->DataArraySelection->GetNumberOfArrays();
}

//------------------------------------------------------------------------------
const char* vtkTecplotReader::GetDataArrayName(int arrayIdx)
{
  return this->DataArraySelection->GetArrayName(arrayIdx);
}

//------------------------------------------------------------------------------
int vtkTecplotReader::GetDataArrayStatus(const char* arayName)
{
  return this->DataArraySelection->ArrayIsEnabled(arayName);
}

//------------------------------------------------------------------------------
void vtkTecplotReader::SetDataArrayStatus(const char* arayName, int bChecked)
{
  vtkDebugMacro("Set cell array \"" << arayName << "\" status to: " << bChecked);

  if (bChecked)
  {
    this->DataArraySelection->EnableArray(arayName);
  }
  else
  {
    this->DataArraySelection->DisableArray(arayName);
  }
}

//------------------------------------------------------------------------------
void vtkTecplotReader::PrintSelf(ostream& os, vtkIndent indent)
{
  this->Superclass::PrintSelf(os, indent);

  os << indent << "DataTitle: " << this->DataTitle << endl;
  os << indent << "Size of CellBased: " << this->CellBased.size() << endl;
  os << indent << "Size of ZoneNames: " << this->ZoneNames.size() << endl;
  os << indent << "Size of Variables: " << this->Variables.size() << endl;
  os << indent << "NumberOfVariables: " << this->NumberOfVariables << endl;
}

//------------------------------------------------------------------------------
void vtkTecplotReader::GetArraysFromPointPackingZone(
  int numNodes, vtkPoints* theNodes, vtkPointData* nodeData)
{
  // NOTE: The Tecplot ASCII file format mandates that cell data of any zone be
  // stored in block-packing mode (VARLOCATION, pp. 158, Tecplot 360 Data Format
  // Guide 2009). Thus we do not need to consider any cell data in this function.

  if (!theNodes || !nodeData || !this->Internal->ASCIIStream.is_open())
  {
    vtkErrorMacro(<< "File not open, errors with reading, or nullptr vtkPoints /"
                  << "vtkPointData.");
    return;
  }

  int n, v;
  int zArrayId; // indexing zoneData
  int cordBase; // offset of a 3D-coordinate triple in cordsPtr
  int isXcoord;
  int isYcoord;
  int isZcoord;
  float theValue;
  std::vector<float*> pointers;
  std::vector<vtkFloatArray*> zoneData;

  pointers.clear();
  zoneData.clear();

  // geometry: 3D point coordinates (note that this array must be initialized
  // since only 2D coordinates might be provided by a Tecplot file)
  theNodes->SetNumberOfPoints(numNodes);
  float* cordsPtr = static_cast<float*>(theNodes->GetVoidPointer(0));
  memset(cordsPtr, 0, sizeof(float) * 3 * numNodes);

  // three arrays used to determine the role of each variable (including
  // the coordinate arrays)
  std::vector<int> anyCoord(this->NumberOfVariables); // is any coordinate?
  std::vector<int> coordIdx(this->NumberOfVariables); // index of the coordinate array, just in case
  std::vector<int> selected(this->NumberOfVariables); // is a selected data array?

  // allocate arrays only if necessary to load the zone data
  for (v = 0; v < this->NumberOfVariables; v++)
  {
    isXcoord = int(!(v - this->Internal->XIdInList));
    isYcoord = int(!(v - this->Internal->YIdInList));
    isZcoord = int(!(v - this->Internal->ZIdInList));
    anyCoord[v] = isXcoord + isYcoord + isZcoord;
    coordIdx[v] = isYcoord + (isZcoord << 1);
    selected[v] = this->DataArraySelection->ArrayIsEnabled(this->Variables[v].c_str());

    if (anyCoord[v] + selected[v])
    {
      vtkFloatArray* theArray = vtkFloatArray::New();
      theArray->SetNumberOfTuples(numNodes);
      theArray->SetName(this->Variables[v].c_str());
      zoneData.push_back(theArray);
      float* arrayPtr = static_cast<float*>(theArray->GetVoidPointer(0));
      pointers.push_back(arrayPtr);
      arrayPtr = nullptr;
      theArray = nullptr;
    }
  }

  // load the zone data (number of tuples <= number of points / nodes)
  for (n = 0; n < numNodes; n++)
  {
    cordBase = (n << 1) + n;

    zArrayId = 0;
    for (v = 0; v < this->NumberOfVariables; v++)
    {
      // obtain a value that is either a coordinate or a selected attribute
      if (anyCoord[v] || selected[v])
      {
        theValue = atof(this->Internal->GetNextToken().c_str());
        pointers[zArrayId++][n] = theValue;

        // collect the coordinate
        if (anyCoord[v])
        {
          cordsPtr[cordBase + coordIdx[v]] = theValue;
        }
      }
      else
      {
        // a value of an un-selected data array
        this->Internal->GetNextToken();
      }
    }
  }
  cordsPtr = nullptr;

  // attach the node-based data attributes to the grid
  zArrayId = 0;
  for (v = 0; v < this->NumberOfVariables; v++)
  {
    if (!anyCoord[v] && selected[v])
    {
      nodeData->AddArray(zoneData[zArrayId]);
    }

    zArrayId += int(!(!(anyCoord[v] + selected[v])));
  }

  pointers.clear();

  // remove all the float arrays from vector so they won't leak
  for (unsigned int i = 0; i < zoneData.size(); ++i)
  {
    vtkFloatArray* fa = zoneData.at(i);
    if (fa)
    {
      fa->FastDelete();
    }
  }
  zoneData.clear();
}

//------------------------------------------------------------------------------
void vtkTecplotReader::GetArraysFromBlockPackingZone(
  int numNodes, int numCells, vtkPoints* theNodes, vtkPointData* nodeData, vtkCellData* cellData)
{
  // NOTE: The Tecplot ASCII file format states that a block-packing zone may
  // contain point data or cell data (VARLOCATION, pp. 158, Tecplot 360 Data
  // Format Guide 2009). Thus we need to consider both cases in this function.

  if (!theNodes || !nodeData || !cellData || !this->Internal->ASCIIStream.is_open())
  {
    vtkErrorMacro(<< "File not open, errors with reading, or nullptr vtkPoints /"
                  << "vtkPointData / vtkCellData.");
    return;
  }

  int v;
  int zArrayId; // indexing zoneData
  int arraySiz;
  int isXcoord;
  int isYcoord;
  int isZcoord;
  std::vector<vtkFloatArray*> zoneData;
  vtkDataSetAttributes* attribute[2] = { nodeData, cellData };

  zoneData.clear();

  // geometry: 3D point coordinates (note that this array must be initialized
  // since only 2D coordinates might be provided by a Tecplot file)
  theNodes->SetNumberOfPoints(numNodes);
  float* cordsPtr = static_cast<float*>(theNodes->GetVoidPointer(0));
  memset(cordsPtr, 0, sizeof(float) * 3 * numNodes);

  // two arrays used to determine the role of each variable (including
  // the coordinate arrays)
  std::vector<int> anyCoord(this->NumberOfVariables); // is any coordinate?
  std::vector<int> selected(this->NumberOfVariables); // is a selected data array?

  for (v = 0; v < this->NumberOfVariables; v++)
  {
    // check if this variable refers to a coordinate array
    isXcoord = int(!(v - this->Internal->XIdInList));
    isYcoord = int(!(v - this->Internal->YIdInList));
    isZcoord = int(!(v - this->Internal->ZIdInList));
    anyCoord[v] = isXcoord + isYcoord + isZcoord;

    // in case of a data attribute, is it selected by the user?
    selected[v] = this->DataArraySelection->ArrayIsEnabled(this->Variables[v].c_str());

    // obtain the size of the block
    arraySiz = (this->CellBased[v] ? numCells : numNodes);

    if (anyCoord[v] || selected[v])
    {
      // parse the block to extract either coordinates or data attribute
      // values

      // extract the variable array throughout a block
      vtkFloatArray* theArray = vtkFloatArray::New();
      theArray->SetNumberOfTuples(arraySiz);
      theArray->SetName(this->Variables[v].c_str());
      zoneData.push_back(theArray);

      float* arrayPtr = static_cast<float*>(theArray->GetVoidPointer(0));
      for (int i = 0; i < arraySiz; i++)
      {
        arrayPtr[i] = atof(this->Internal->GetNextToken().c_str());
      }
      theArray = nullptr;

      // three special arrays are 'combined' to fill the 3D coord array
      if (anyCoord[v])
      {
        float* coordPtr = cordsPtr + isYcoord + (isZcoord << 1);
        for (int i = 0; i < arraySiz; i++, coordPtr += 3)
        {
          *coordPtr = arrayPtr[i];
        }
        coordPtr = nullptr;
      }

      arrayPtr = nullptr;
    }
    else
    {
      // this block contains an un-selected data attribute and we
      // need to read but ignore the values
      for (int i = 0; i < arraySiz; i++)
      {
        this->Internal->GetNextToken();
      }
    }
  }
  cordsPtr = nullptr;

  // attach the dataset attributes (node-based and cell-based) to the grid
  // NOTE: zoneData[] and this->Variables (and this->CellBased) may differ
  // in the number of the maintained arrays
  zArrayId = 0;
  for (v = 0; v < this->NumberOfVariables; v++)
  {
    if (!anyCoord[v] && selected[v])
    {
      attribute[this->CellBased[v]]->AddArray(zoneData[zArrayId]);
    }

    zArrayId += int(!(!(anyCoord[v] + selected[v])));
  }

  // remove all the float arrays from vector so they won't leak
  for (unsigned int i = 0; i < zoneData.size(); ++i)
  {
    vtkFloatArray* fa = zoneData.at(i);
    if (fa)
    {
      fa->FastDelete();
    }
  }
  zoneData.clear();
  attribute[0] = attribute[1] = nullptr;
}

//------------------------------------------------------------------------------
void vtkTecplotReader::GetStructuredGridFromBlockPackingZone(int iDimSize, int jDimSize,
  int kDimSize, int zoneIndx, const char* zoneName, vtkMultiBlockDataSet* multZone)
{
  if (!zoneName || !multZone)
  {
    vtkErrorMacro("Zone name un-specified or nullptr vtkMultiBlockDataSet.");
    return;
  }

  // determine the topological dimension
  if (jDimSize == 1 && kDimSize == 1)
  {
    this->Internal->TopologyDim = vtkMath::Max(this->Internal->TopologyDim, 1);
  }
  else if (kDimSize == 1)
  {
    this->Internal->TopologyDim = vtkMath::Max(this->Internal->TopologyDim, 2);
  }
  else
  {
    this->Internal->TopologyDim = vtkMath::Max(this->Internal->TopologyDim, 3);
  }

  // number of points, number of cells, and dimensionality
  int numNodes = iDimSize * jDimSize * kDimSize;
  int numCells = ((iDimSize <= 1) ? 1 : (iDimSize - 1)) * ((jDimSize <= 1) ? 1 : (jDimSize - 1)) *
    ((kDimSize <= 1) ? 1 : (kDimSize - 1));
  int gridDims[3] = { iDimSize, jDimSize, kDimSize };

  // Create vtkPoints and vtkStructuredGrid and associate them
  vtkPoints* pntCords = vtkPoints::New();
  vtkStructuredGrid* strcGrid = vtkStructuredGrid::New();
  this->GetArraysFromBlockPackingZone(
    numNodes, numCells, pntCords, strcGrid->GetPointData(), strcGrid->GetCellData());
  strcGrid->SetDimensions(gridDims);
  strcGrid->SetPoints(pntCords);
  pntCords->Delete();
  pntCords = nullptr;

  if ((this->Internal->TopologyDim == 2 || this->Internal->TopologyDim == 3) ||
    ((this->Internal->TopologyDim == 0 || this->Internal->TopologyDim == 1) &&
      this->Internal->GeometryDim > 1))
  {
    multZone->SetBlock(zoneIndx, strcGrid);
    multZone->GetMetaData(zoneIndx)->Set(vtkCompositeDataSet::NAME(), zoneName);
  }
  strcGrid->Delete();
  strcGrid = nullptr;
}

//------------------------------------------------------------------------------
void vtkTecplotReader::GetStructuredGridFromPointPackingZone(int iDimSize, int jDimSize,
  int kDimSize, int zoneIndx, const char* zoneName, vtkMultiBlockDataSet* multZone)
{
  if (!zoneName || !multZone)
  {
    vtkErrorMacro("Zone name un-specified or nullptr vtkMultiBlockDataSet.");
    return;
  }

  if (jDimSize == 1 && kDimSize == 1)
  {
    this->Internal->TopologyDim = vtkMath::Max(this->Internal->TopologyDim, 1);
  }
  else if (kDimSize == 1)
  {
    this->Internal->TopologyDim = vtkMath::Max(this->Internal->TopologyDim, 2);
  }
  else
  {
    this->Internal->TopologyDim = vtkMath::Max(this->Internal->TopologyDim, 3);
  }

  // number of points, number of cells, and dimensionality
  int numNodes = iDimSize * jDimSize * kDimSize;
  int gridDims[3] = { iDimSize, jDimSize, kDimSize };

  // Create vtkPoints and vtkStructuredGrid and associate them
  vtkPoints* pntCords = vtkPoints::New();
  vtkStructuredGrid* strcGrid = vtkStructuredGrid::New();
  this->GetArraysFromPointPackingZone(numNodes, pntCords, strcGrid->GetPointData());
  strcGrid->SetDimensions(gridDims);
  strcGrid->SetPoints(pntCords);
  pntCords->Delete();
  pntCords = nullptr;

  if ((this->Internal->TopologyDim == 2 || this->Internal->TopologyDim == 3) ||
    (this->Internal->TopologyDim == 0 && this->Internal->GeometryDim > 1))
  {
    multZone->SetBlock(zoneIndx, strcGrid);
    multZone->GetMetaData(zoneIndx)->Set(vtkCompositeDataSet::NAME(), zoneName);
  }
  strcGrid->Delete();
  strcGrid = nullptr;
}

void vtkTecplotReader::GetPolygonalGridFromBlockPackingZone(int numNodes, int numCells,
  int numFaces, int zoneIndx, const char* zoneName, vtkMultiBlockDataSet* multZone)
{
  vtkPoints* gridPnts = vtkPoints::New();
  vtkUnstructuredGrid* unstruct = vtkUnstructuredGrid::New();
  this->GetArraysFromBlockPackingZone(
    numNodes, numCells, gridPnts, unstruct->GetPointData(), unstruct->GetCellData());

  unstruct->SetPoints(gridPnts);
  gridPnts->Delete();
  gridPnts = nullptr;

  this->GetPolygonalGridCells(numCells, numFaces, unstruct);

  if ((this->Internal->TopologyDim == 2 || this->Internal->TopologyDim == 3) ||
    (this->Internal->TopologyDim == 0 && this->Internal->GeometryDim > 1))
  {
    multZone->SetBlock(zoneIndx, unstruct);
    multZone->GetMetaData(zoneIndx)->Set(vtkCompositeDataSet::NAME(), zoneName);
  }
  unstruct->Delete();
  unstruct = nullptr;
}

void vtkTecplotReader::GetPolyhedralGridFromBlockPackingZone(int numNodes, int numCells,
  int numFaces, int zoneIndx, const char* zoneName, vtkMultiBlockDataSet* multZone)
{
  vtkPoints* gridPnts = vtkPoints::New();
  vtkUnstructuredGrid* unstruct = vtkUnstructuredGrid::New();
  this->GetArraysFromBlockPackingZone(
    numNodes, numCells, gridPnts, unstruct->GetPointData(), unstruct->GetCellData());

  unstruct->SetPoints(gridPnts);
  gridPnts->Delete();
  gridPnts = nullptr;

  this->GetPolyhedralGridCells(numCells, numFaces, unstruct);

  if ((this->Internal->TopologyDim == 2 || this->Internal->TopologyDim == 3) ||
    (this->Internal->TopologyDim == 0 && this->Internal->GeometryDim > 1))
  {
    multZone->SetBlock(zoneIndx, unstruct);
    multZone->GetMetaData(zoneIndx)->Set(vtkCompositeDataSet::NAME(), zoneName);
  }
  unstruct->Delete();
  unstruct = nullptr;
}

//------------------------------------------------------------------------------
void vtkTecplotReader::GetUnstructuredGridFromBlockPackingZone(int numNodes, int numCells,
  const char* cellType, int zoneIndx, const char* zoneName, vtkMultiBlockDataSet* multZone)
{
  if (!cellType || !zoneName || !multZone)
  {
    vtkErrorMacro(<< "Zone name / cell type un-specified, or nullptr "
                  << "vtkMultiBlockDataSet object.");
    return;
  }

  vtkPoints* gridPnts = vtkPoints::New();
  vtkUnstructuredGrid* unstruct = vtkUnstructuredGrid::New();
  this->GetArraysFromBlockPackingZone(
    numNodes, numCells, gridPnts, unstruct->GetPointData(), unstruct->GetCellData());
  this->GetUnstructuredGridCells(numCells, cellType, unstruct);
  unstruct->SetPoints(gridPnts);
  gridPnts->Delete();
  gridPnts = nullptr;

  if ((this->Internal->TopologyDim == 2 || this->Internal->TopologyDim == 3) ||
    (this->Internal->TopologyDim == 0 && this->Internal->GeometryDim > 1))
  {
    multZone->SetBlock(zoneIndx, unstruct);
    multZone->GetMetaData(zoneIndx)->Set(vtkCompositeDataSet::NAME(), zoneName);
  }
  unstruct->Delete();
  unstruct = nullptr;
}

//------------------------------------------------------------------------------
void vtkTecplotReader::GetUnstructuredGridFromPointPackingZone(int numNodes, int numCells,
  const char* cellType, int zoneIndx, const char* zoneName, vtkMultiBlockDataSet* multZone)
{
  if (!cellType || !zoneName || !multZone)
  {
    vtkErrorMacro(<< "Zone name / cell type un-specified, or nullptr "
                  << "vtkMultiBlockDataSet object.");
    return;
  }

  vtkPoints* gridPnts = vtkPoints::New();
  vtkUnstructuredGrid* unstruct = vtkUnstructuredGrid::New();
  this->GetArraysFromPointPackingZone(numNodes, gridPnts, unstruct->GetPointData());
  this->GetUnstructuredGridCells(numCells, cellType, unstruct);
  unstruct->SetPoints(gridPnts);
  gridPnts->Delete();
  gridPnts = nullptr;

  if ((this->Internal->TopologyDim == 2 || this->Internal->TopologyDim == 3) ||
    (this->Internal->TopologyDim == 0 && this->Internal->GeometryDim > 1))
  {
    multZone->SetBlock(zoneIndx, unstruct);
    multZone->GetMetaData(zoneIndx)->Set(vtkCompositeDataSet::NAME(), zoneName);
  }
  unstruct->Delete();
  unstruct = nullptr;
}

void vtkTecplotReader::GetPolyhedralGridCells(
  int numCells, int numFaces, vtkUnstructuredGrid* unstruct) const
{
  auto tok = this->Internal->GetNextToken();
  while (tok.empty())
  {
    tok = this->Internal->GetNextToken();
  }

  std::vector<size_t> nodeCountPerFace;
  nodeCountPerFace.push_back(static_cast<size_t>(atoi(tok.c_str())));

  for (vtkIdType i = 1; i < numFaces; ++i)
  {
    tok = this->Internal->GetNextToken();
    while (tok.empty())
    {
      tok = this->Internal->GetNextToken();
    }
    nodeCountPerFace.push_back(static_cast<size_t>(atoi(tok.c_str())));
  }

  std::vector<std::vector<vtkIdType>> faces;
  for (vtkIdType i = 0; i < numFaces; ++i)
  {
    const size_t nodeCount = nodeCountPerFace[i];
    std::vector<vtkIdType> face;
    face.reserve(nodeCount);

    for (size_t j = 0; j < nodeCount; ++j)
    {
      tok = this->Internal->GetNextToken();
      while (tok.empty())
      {
        tok = this->Internal->GetNextToken();
      }
      auto aVertexIndex = static_cast<vtkIdType>(atoi(tok.c_str()));
      face.push_back(aVertexIndex - 1); // convert from FORTRAN to C-indexing
    }

    faces.push_back(face);
  }

  std::map<vtkIdType, std::vector<vtkIdType>> polyhedra;

  for (vtkIdType i = 0; i < numFaces; ++i)
  {
    tok = this->Internal->GetNextToken();
    while (tok.empty())
    {
      tok = this->Internal->GetNextToken();
    }
    const auto rightCell = static_cast<vtkIdType>(atoi(tok.c_str()));
    if (rightCell > 0)
    {
      polyhedra[rightCell - 1].push_back(i);
    }
  }

  for (vtkIdType i = 0; i < numFaces; ++i)
  {
    tok = this->Internal->GetNextToken();
    while (tok.empty())
    {
      tok = this->Internal->GetNextToken();
    }
    const auto leftCell = static_cast<vtkIdType>(atoi(tok.c_str()));
    if (leftCell > 0)
    {
      polyhedra[leftCell - 1].push_back(i);
    }
  }

  for (auto& entry : polyhedra)
  {
    const auto& facesOfPolyhedron = entry.second;
    std::vector<vtkIdType> polyhedron;

    for (auto& aFaceIndex : facesOfPolyhedron)
    {
      const auto& aFace = faces[aFaceIndex];
      const auto faceSize = static_cast<vtkIdType>(aFace.size());
      polyhedron.push_back(faceSize);
      for (auto& aVertexIndex : aFace)
      {
        polyhedron.push_back(aVertexIndex);
      }
    }
    unstruct->InsertNextCell(
      VTK_POLYHEDRON, static_cast<vtkIdType>(facesOfPolyhedron.size()), polyhedron.data());
  }

  if (unstruct->GetNumberOfCells() != numCells)
  {
    vtkWarningMacro(<< "Number of polyhedral cells does not match.");
  }
}

void OrderEdges(const std::vector<vtkIdType>& faceEdges,
  const std::vector<std::pair<vtkIdType, vtkIdType>>& allEdges, vtkIdList* face)
{
  face->Reset();
  if (faceEdges.empty())
    return;

  const auto& firstEdge = allEdges[faceEdges[0]];
  const vtkIdType from = firstEdge.first;
  face->InsertNextId(from);
  vtkIdType to = firstEdge.second;
  face->InsertNextId(to);

  size_t i = 0;
  while (to != from)
  {
    for (size_t j = 0; j < faceEdges.size(); ++j)
    {
      if (i == j)
        continue;

      const auto& edge = allEdges[faceEdges[j]];
      if (edge.first == to)
      {
        to = edge.second;
        i = j;
        face->InsertNextId(to);
        break;
      }
      else if (edge.second == to)
      {
        to = edge.first;
        i = j;
        face->InsertNextId(to);
        break;
      }
    }

    if (face->GetNumberOfIds() > static_cast<vtkIdType>(faceEdges.size() + 1))
    {
      // should not happen, but better exit than ending up in a continuous loop
      break;
    }
  }

  face->Resize(face->GetNumberOfIds() - 1);
}

void vtkTecplotReader::GetPolygonalGridCells(
  int numFaces, int numEdges, vtkUnstructuredGrid* unstruct) const
{
  std::vector<std::pair<vtkIdType, vtkIdType>> edges;

  for (int i = 0; i < numEdges; ++i)
  {
    auto tok1 = this->Internal->GetNextToken();
    while (tok1.empty())
    {
      tok1 = this->Internal->GetNextToken();
    }
    auto tok2 = this->Internal->GetNextToken();
    while (tok2.empty())
    {
      tok2 = this->Internal->GetNextToken();
    }

    const auto e1 = static_cast<vtkIdType>(atoi(tok1.c_str()));
    const auto e2 = static_cast<vtkIdType>(atoi(tok2.c_str()));
    edges.emplace_back(e1 - 1, e2 - 1); // convert from FORTRAN to C-indexing
  }

  std::map<vtkIdType, std::vector<vtkIdType>> faceEdges;

  for (int i = 0; i < numEdges; ++i)
  {
    auto tok = this->Internal->GetNextToken();
    while (tok.empty())
    {
      tok = this->Internal->GetNextToken();
    }

    const auto leftElement = static_cast<vtkIdType>(atoi(tok.c_str()));
    if (leftElement > 0)
    {
      faceEdges[leftElement - 1].push_back(i);
    }
  }

  for (int i = 0; i < numEdges; ++i)
  {
    auto tok = this->Internal->GetNextToken();
    while (tok.empty())
    {
      tok = this->Internal->GetNextToken();
    }

    const auto rightElement = static_cast<vtkIdType>(atoi(tok.c_str()));
    if (rightElement > 0)
    {
      faceEdges[rightElement - 1].push_back(i);
    }
  }

  if (faceEdges.size() != static_cast<size_t>(numFaces))
  {
    vtkWarningMacro(<< " number of faces does not match.");
  }

  vtkNew<vtkIdList> face;
  for (auto& entry : faceEdges)
  {
    OrderEdges(entry.second, edges, face);
    unstruct->InsertNextCell(VTK_POLYGON, face->GetNumberOfIds(), face->GetPointer(0));
  }
}

//------------------------------------------------------------------------------
void vtkTecplotReader::GetUnstructuredGridCells(
  int numberCells, const char* cellTypeStr, vtkUnstructuredGrid* unstrctGrid)
{
  if (!cellTypeStr || !unstrctGrid)
  {
    vtkErrorMacro(<< "Cell type (connectivity type) unspecified or nullptr "
                  << "vtkUnstructuredGrid object.");
    return;
  }

  // determine the number of points per cell and the cell type
  int numCellPnts = -1;
  int theCellType = -1;

  if (strcmp(cellTypeStr, "BRICK") == 0)
  {
    numCellPnts = 8;
    theCellType = VTK_HEXAHEDRON;
    this->Internal->TopologyDim = vtkMath::Max(this->Internal->TopologyDim, 3);
  }
  else if (strcmp(cellTypeStr, "TRIANGLE") == 0)
  {
    numCellPnts = 3;
    theCellType = VTK_TRIANGLE;
    this->Internal->TopologyDim = vtkMath::Max(this->Internal->TopologyDim, 2);
  }
  else if (strcmp(cellTypeStr, "QUADRILATERAL") == 0)
  {
    numCellPnts = 4;
    theCellType = VTK_QUAD;
    this->Internal->TopologyDim = vtkMath::Max(this->Internal->TopologyDim, 2);
  }
  else if (strcmp(cellTypeStr, "TETRAHEDRON") == 0)
  {
    numCellPnts = 4;
    theCellType = VTK_TETRA;
    this->Internal->TopologyDim = vtkMath::Max(this->Internal->TopologyDim, 3);
  }
  else if (strcmp(cellTypeStr, "POINT") == 0 || strcmp(cellTypeStr, "") == 0)
  {
    numCellPnts = 1;
    theCellType = VTK_VERTEX;
    this->Internal->TopologyDim = vtkMath::Max(this->Internal->TopologyDim, 0);
  }
  else
  {
    vtkErrorMacro(<< this->FileName << ": Unknown cell type for a zone.");
    return;
  }

  // the storage of each cell begins with the number of points per cell,
  // followed by a list of point ids representing the cell
  vtkIdTypeArray* cellInfoList = vtkIdTypeArray::New();
  cellInfoList->SetNumberOfValues((numCellPnts + 1) * numberCells);
  vtkIdType* cellInforPtr = cellInfoList->GetPointer(0);

  // type of each cell
  vtkUnsignedCharArray* cellTypeList = vtkUnsignedCharArray::New();
  cellTypeList->SetNumberOfValues(numberCells);
  unsigned char* cellTypesPtr = cellTypeList->GetPointer(0);

  // fill the three arrays
  for (int c = 0; c < numberCells; c++)
  {
    *cellTypesPtr++ = theCellType;
    *cellInforPtr++ = numCellPnts;

    // 1-origin connectivity array
    for (int j = 0; j < numCellPnts; j++)
    {
      *cellInforPtr++ =
        (theCellType == VTK_VERTEX ? c : atoi(this->Internal->GetNextToken().c_str()) - 1);
    }
  }
  cellInforPtr = nullptr;
  cellTypesPtr = nullptr;

  // create a cell array object to accept the cell info
  vtkCellArray* theCellArray = vtkCellArray::New();
  theCellArray->ImportLegacyFormat(cellInfoList);
  cellInfoList->Delete();
  cellInfoList = nullptr;

  // create a vtkUnstructuredGrid object and attach the 3 arrays (types, locations,
  // and cells) to it for export.
  unstrctGrid->SetCells(cellTypeList, theCellArray);
  theCellArray->Delete();
  cellTypeList->Delete();
  theCellArray = nullptr;
  cellTypeList = nullptr;
}

//------------------------------------------------------------------------------
void vtkTecplotReader::GetDataArraysList()
{
  if ((this->Internal->Completed == 1) || (this->DataArraySelection->GetNumberOfArrays() > 0) ||
    (this->FileName == nullptr) || (strcmp(this->FileName, "") == 0))
  {
    return;
  }

#define READ_UNTIL_TITLE_OR_VARIABLES                                                              \
  !this->Internal->NextCharEOF && theTpToken != "TITLE" && theTpToken != "VARIABLES"
  int i;
  int tpTokenLen = 0;
  int guessedXid = -1;
  int guessedYid = -1;
  int guessedZid = -1;
  bool tokenReady = false;
  std::string noSpaceTok;

  this->Variables.clear();
  this->NumberOfVariables = 0;

  this->Internal->Init();
  this->Internal->ASCIIStream.open(this->FileName);
  std::string theTpToken = this->Internal->GetNextToken();

  while (!this->Internal->NextCharEOF)
  {
    tokenReady = false;

    if (theTpToken.empty())
    {
      // whitespace: do nothing
    }
    else if (theTpToken == "TITLE")
    {
      this->Internal->GetNextToken();
    }
    else if (theTpToken == "VARIABLES")
    {
      theTpToken = this->Internal->GetNextToken();

      while (this->Internal->TokenIsString)
      {
        tpTokenLen = int(theTpToken.length());
        for (i = 0; i < tpTokenLen; i++)
        {
          if (theTpToken[i] == '(')
          {
            theTpToken[i] = '[';
          }
          else if (theTpToken[i] == ')')
          {
            theTpToken[i] = ']';
          }
          else if (theTpToken[i] == '/')
          {
            theTpToken[i] = '_';
          }
        }

        noSpaceTok = SimplifyWhitespace(theTpToken);

        switch (GetCoord(noSpaceTok))
        {
          case 0:
            this->Internal->XIdInList = this->NumberOfVariables;
            break;
          case 1:
            this->Internal->YIdInList = this->NumberOfVariables;
            break;
          case 2:
            this->Internal->ZIdInList = this->NumberOfVariables;
            break;
          default:
            break;
        }

        switch (GuessCoord(noSpaceTok))
        {
          case 0:
            guessedXid = this->NumberOfVariables;
            break;
          case 1:
            guessedYid = this->NumberOfVariables;
            break;
          case 2:
            guessedZid = this->NumberOfVariables;
            break;
          default:
            break;
        }

        this->Variables.push_back(theTpToken);
        this->NumberOfVariables++;
        theTpToken = this->Internal->GetNextToken();
      }

      if (this->NumberOfVariables == 0)
      {
        while (true)
        {
          noSpaceTok = SimplifyWhitespace(theTpToken);

          switch (GetCoord(noSpaceTok))
          {
            case 0:
              this->Internal->XIdInList = this->NumberOfVariables;
              break;
            case 1:
              this->Internal->YIdInList = this->NumberOfVariables;
              break;
            case 2:
              this->Internal->ZIdInList = this->NumberOfVariables;
              break;
            default:
              break;
          }

          switch (GuessCoord(noSpaceTok))
          {
            case 0:
              guessedXid = this->NumberOfVariables;
              break;
            case 1:
              guessedYid = this->NumberOfVariables;
              break;
            case 2:
              guessedZid = this->NumberOfVariables;
              break;
            default:
              break;
          }

          this->Variables.push_back(theTpToken);
          this->NumberOfVariables++;

          if (this->Internal->NextCharEOL)
          {
            break;
          }
          theTpToken = this->Internal->GetNextToken();
        }
      }

      // in case there is not an exact match for coordinate axis vars
      this->Internal->XIdInList =
        (this->Internal->XIdInList < 0) ? guessedXid : this->Internal->XIdInList;
      this->Internal->YIdInList =
        (this->Internal->YIdInList < 0) ? guessedYid : this->Internal->YIdInList;
      this->Internal->ZIdInList =
        (this->Internal->ZIdInList < 0) ? guessedZid : this->Internal->ZIdInList;

      break;
    }
    else
    {
      do
      {
        theTpToken = this->Internal->GetNextToken();
      } while (READ_UNTIL_TITLE_OR_VARIABLES);

      tokenReady = true;
    }

    if (!tokenReady)
    {
      theTpToken = this->Internal->GetNextToken();
    }
  }

  this->Internal->ASCIIStream.rewind();

  // register the data arrays
  for (i = 0; i < this->GetNumberOfDataAttributes(); i++)
  {
    // all data arrays are selected here by default
    this->DataArraySelection->EnableArray(this->GetDataAttributeName(i));
  }
}

//------------------------------------------------------------------------------
void vtkTecplotReader::ReadFile(vtkMultiBlockDataSet* multZone)
{
  if ((this->Internal->Completed == 1) || (this->FileName == nullptr) ||
    (strcmp(this->FileName, "") == 0))
  {
    return;
  }

  if (multZone == nullptr)
  {
    vtkErrorMacro("vtkMultiBlockDataSet multZone nullptr!");
    return;
  }

#define READ_UNTIL_LINE_END                                                                        \
  !this->Internal->NextCharEOF && tok != "TITLE" && tok != "VARIABLES" && tok != "ZONE" &&         \
    tok != "GEOMETRY" && tok != "TEXT" && tok != "DATASETAUXDATA"
  int zoneIndex = 0;
  bool firstToken = true;
  bool tokenReady = false;

  this->Init();
  this->Internal->ASCIIStream.open(this->FileName);
  std::string tok = this->Internal->GetNextToken();

  while (!this->Internal->NextCharEOF)
  {
    tokenReady = false;
    if (tok.empty())
    {
      // whitespace: do nothing
    }
    else if (tok == "TITLE")
    {
      this->DataTitle = this->Internal->GetNextToken();
    }
    else if (tok == "GEOMETRY")
    {
      // unsupported
      tok = this->Internal->GetNextToken();
      while (READ_UNTIL_LINE_END)
      {
        // skipping token
        tok = this->Internal->GetNextToken();
      }
      tokenReady = true;
    }
    else if (tok == "TEXT")
    {
      // unsupported
      tok = this->Internal->GetNextToken();
      while (READ_UNTIL_LINE_END)
      {
        // Skipping token
        tok = this->Internal->GetNextToken();
      }
      tokenReady = true;
    }
    else if (tok == "VARIABLES")
    {
      int guessedXindex = -1;
      int guessedYindex = -1;
      int guessedZindex = -1;

      // variable lists
      tok = this->Internal->GetNextToken();
      while (this->Internal->TokenIsString)
      {
        int tokLen = int(tok.length());
        for (int i = 0; i < tokLen; i++)
        {
          if (tok[i] == '(')
          {
            tok[i] = '[';
          }
          else if (tok[i] == ')')
          {
            tok[i] = ']';
          }
          else if (tok[i] == '/')
          {
            tok[i] = '_';
          }
        }

        std::string tok_nw = SimplifyWhitespace(tok);

        switch (GetCoord(tok_nw))
        {
          case 0:
            this->Internal->XIdInList = this->NumberOfVariables;
            break;
          case 1:
            this->Internal->YIdInList = this->NumberOfVariables;
            break;
          case 2:
            this->Internal->ZIdInList = this->NumberOfVariables;
            break;
          default:
            break;
        }

        switch (GuessCoord(tok_nw))
        {
          case 0:
            guessedXindex = this->NumberOfVariables;
            break;
          case 1:
            guessedYindex = this->NumberOfVariables;
            break;
          case 2:
            guessedZindex = this->NumberOfVariables;
            break;
          default:
            break;
        }

        this->Variables.push_back(tok);
        this->NumberOfVariables++;
        tok = this->Internal->GetNextToken();
      }

      if (this->NumberOfVariables == 0)
      {
        while (true)
        {
          std::string tok_nw = SimplifyWhitespace(tok);

          switch (GetCoord(tok_nw))
          {
            case 0:
              this->Internal->XIdInList = this->NumberOfVariables;
              break;
            case 1:
              this->Internal->YIdInList = this->NumberOfVariables;
              break;
            case 2:
              this->Internal->ZIdInList = this->NumberOfVariables;
              break;
            default:
              break;
          }

          switch (GuessCoord(tok_nw))
          {
            case 0:
              guessedXindex = this->NumberOfVariables;
              break;
            case 1:
              guessedYindex = this->NumberOfVariables;
              break;
            case 2:
              guessedZindex = this->NumberOfVariables;
              break;
            default:
              break;
          }

          this->Variables.push_back(tok);
          this->NumberOfVariables++;

          if (this->Internal->NextCharEOL)
          {
            tok = this->Internal->GetNextToken();
            break;
          }
          else
          {
            tok = this->Internal->GetNextToken();
          }
        }
      }

      // Default the centering to nodal
      this->CellBased.clear();
      this->CellBased.resize(this->NumberOfVariables, 0);

      // If we didn't find an exact match for coordinate axis vars, guess
      if (this->Internal->XIdInList < 0)
      {
        this->Internal->XIdInList = guessedXindex;
      }
      if (this->Internal->YIdInList < 0)
      {
        this->Internal->YIdInList = guessedYindex;
      }
      if (this->Internal->ZIdInList < 0)
      {
        this->Internal->ZIdInList = guessedZindex;
      }

      // Based on how many spatial coords we got, guess the spatial dim
      if (this->Internal->XIdInList >= 0)
      {
        this->Internal->GeometryDim = 1;
        if (this->Internal->YIdInList >= 0)
        {
          this->Internal->GeometryDim = 2;
          if (this->Internal->ZIdInList >= 0)
          {
            this->Internal->GeometryDim = 3;
          }
        }
      }

      tokenReady = true;
    }
    else if (tok == "ZONE")
    {
      int numI = 1;
      int numJ = 1;
      int numK = 1;
      int numNodes = 0;
      int numFaces = 0;
      int numConnectedBoundaryFaces(-1);
      int totalNumBoundaryConnections(-1);
      int numElements = 0;
      char untitledZoneName[40];
      snprintf(untitledZoneName, sizeof(untitledZoneName), "zone%05d", zoneIndex);

      std::string format;
      std::string elemType;
      std::string zoneType;
      std::string ZoneName = untitledZoneName;

      tok = this->Internal->GetNextToken();
      // instead of looking for known keywords, read the zone header until the first numeric token
      while (!(tok.front() == '-') && !(tok.front() == '.') && !isdigit(tok.front()))
      {
        if (tok == "T")
        {
          ZoneName = this->Internal->GetNextToken();
          if (!this->Internal->TokenIsString)
          {
            vtkErrorMacro(<< this->FileName << ": Zone titles MUST be "
                          << "quoted.");
            return;
          }
        }
        else if (tok == "I")
        {
          numI = atoi(this->Internal->GetNextToken().c_str());
        }
        else if (tok == "J")
        {
          numJ = atoi(this->Internal->GetNextToken().c_str());
        }
        else if (tok == "K")
        {
          numK = atoi(this->Internal->GetNextToken().c_str());
        }
        else if (tok == "N" || tok == "NODES")
        {
          numNodes = atoi(this->Internal->GetNextToken().c_str());
        }
        else if (tok == "E" || tok == "ELEMENTS")
        {
          numElements = atoi(this->Internal->GetNextToken().c_str());
        }
        else if (tok == "ET")
        {
          elemType = this->Internal->GetNextToken();
        }
        else if (tok == "ZONETYPE")
        {
          zoneType = this->Internal->GetNextToken();
        }
        else if (tok == "F" || tok == "DATAPACKING")
        {
          format = this->Internal->GetNextToken();
        }
        else if (tok == "VARLOCATION")
        {
          std::string centering;
          this->CellBased.clear();
          this->CellBased.resize(this->NumberOfVariables, 0);

          // read token to ascertain VARLOCATION syntax usage
          std::string var_format_type = this->Internal->GetNextToken();

          // if each variable will have data type specified explicitly (as is handled in old Tecplot
          // reader), else a range is specified for CELLCENTERED only, with NODAL values assumed
          // implicitly
          if (var_format_type == "NODAL" || var_format_type == "CELLCENTERED")
          {
            if (var_format_type == "CELLCENTERED")
            {
              this->CellBased[0] = 1;
            }
            for (int i = 1; i < this->NumberOfVariables; i++)
            {
              centering = this->Internal->GetNextToken();
              if (centering == "CELLCENTERED")
              {
                this->CellBased[i] = 1;
              }
            }
          }
          else
          {
            do
            {
              // remove left square bracket, if it exists
              size_t brack_pos = var_format_type.find('[');
              if (brack_pos != std::string::npos)
                var_format_type.erase(brack_pos, brack_pos + 1);

              // remove right square bracket, if it exists
              brack_pos = var_format_type.find(']');
              if (brack_pos != std::string::npos)
                var_format_type.erase(brack_pos, brack_pos + 1);

              // if a range is defined, then split again, convert to int and set to cell data
              // else if a single value is defined, then just set the flag directly
              if (var_format_type.find('-') != std::string::npos)
              {
                std::vector<std::string> var_range;
                vtksys::SystemTools::Split(var_format_type, var_range, '-');

                int cell_start = atoi(var_range[0].c_str()) - 1;
                int cell_end = atoi(var_range[1].c_str());
                for (int i = cell_start; i != cell_end; ++i)
                {
                  this->CellBased[i] = 1;
                }
              }
              else
              {
                int index = atoi(var_format_type.c_str()) - 1;
                this->CellBased[index] = 1;
              }

              // get next value
              var_format_type = this->Internal->GetNextToken();

              // continue until the CELLCENTERED keyword is found
            } while (var_format_type != "CELLCENTERED");
          }
        }
        else if (tok == "DT")
        {
          for (int i = 0; i < this->NumberOfVariables; i++)
          {
            this->Internal->GetNextToken();
          }
        }
        else if (tok == "D")
        {
          vtkWarningMacro(<< this->FileName << "; Tecplot zone record parameter "
                          << "'D' is currently unsupported.");
          this->Internal->GetNextToken();
        }
        else if (tok == "STRANDID")
        {
          vtkWarningMacro(<< this->FileName << "; Tecplot zone record parameter "
                          << "'STRANDID' is currently unsupported.");
          this->Internal->GetNextToken();
        }
        else if (tok == "SOLUTIONTIME")
        {
          vtkWarningMacro(<< this->FileName << "; Tecplot zone record parameter "
                          << "'SOLUTIONTIME' is currently unsupported.");
          this->Internal->GetNextToken();
        }
        else if (tok == "PARENTZONE")
        {
          vtkWarningMacro(<< this->FileName << "; Tecplot zone record parameter "
                          << "'PARENTZONE' is currently unsupported.");
          this->Internal->GetNextToken();
        }
        else if (tok == "AUXDATA")
        {
          while (READ_UNTIL_LINE_END)
          {
            // Skipping token
            tok = this->Internal->GetNextToken();

            // the READ_UNTIL_LINE_END macro does NOT read until a line ends
            // but it reads until a next known keyword is encountered.
            if (this->Internal->NextCharEOL)
            {
              break;
            }
          }
        }
        else if (tok == "FACES")
        {
          numFaces = atoi(this->Internal->GetNextToken().c_str());
        }
        else if (tok == "TOTALNUMFACENODES")
        {
          // this parameter is not used
          this->Internal->GetNextToken();
        }
        else if (tok == "NUMCONNECTEDBOUNDARYFACES")
        {
          numConnectedBoundaryFaces = atoi(this->Internal->GetNextToken().c_str());
          if (0 != numConnectedBoundaryFaces)
          {
            vtkWarningMacro(<< "Non-zero number of connected boundary faces is not supported.");
          }
        }
        else if (tok == "TOTALNUMBOUNDARYCONNECTIONS")
        {
          totalNumBoundaryConnections = atoi(this->Internal->GetNextToken().c_str());
          if (0 != totalNumBoundaryConnections)
          {
            vtkWarningMacro(<< "Non-zero number of total #boundary faces is not supported.");
          }
        }
        else
        {
          vtkDebugMacro(<< this->FileName << "; encountered an unknown token: '" << tok
                        << "'. This will be skipped.");
        }
        tok = this->Internal->GetNextToken();
      } // end while loop looking for known tokens

      this->Internal->TokenBackup = tok;

      this->ZoneNames.push_back(ZoneName);

      if (zoneType.empty())
      {
        if (format == "FEBLOCK")
        {
          this->GetUnstructuredGridFromBlockPackingZone(
            numNodes, numElements, elemType.c_str(), zoneIndex, ZoneName.c_str(), multZone);
        }
        else if (format == "FEPOINT")
        {
          this->GetUnstructuredGridFromPointPackingZone(
            numNodes, numElements, elemType.c_str(), zoneIndex, ZoneName.c_str(), multZone);
        }
        else if (format == "BLOCK")
        {
          this->GetStructuredGridFromBlockPackingZone(
            numI, numJ, numK, zoneIndex, ZoneName.c_str(), multZone);
        }
        else if (format == "POINT")
        {
          this->GetStructuredGridFromPointPackingZone(
            numI, numJ, numK, zoneIndex, ZoneName.c_str(), multZone);
        }
        else if (format.empty())
        {
          // No format given; we will assume we got a POINT format
          this->GetStructuredGridFromPointPackingZone(
            numI, numJ, numK, zoneIndex, ZoneName.c_str(), multZone);
        }
        else
        {
          // UNKNOWN FORMAT
          vtkErrorMacro(<< this->FileName << ": The format " << format
                        << " found in the file is unknown.");
          return;
        }
      }
      else
      {
        if (zoneType == "ORDERED")
        {
          if (format == "POINT")
          {
            this->GetStructuredGridFromPointPackingZone(
              numI, numJ, numK, zoneIndex, ZoneName.c_str(), multZone);
          }
          else if (format == "BLOCK")
          {
            this->GetStructuredGridFromPointPackingZone(
              numI, numJ, numK, zoneIndex, ZoneName.c_str(), multZone);
          }
        }
        else if (zoneType == "FETRIANGLE" || zoneType == "FEQUADRILATERAL" ||
          zoneType == "FEBRICK" || zoneType == "FETETRAHEDRON")
        {
          std::string elType = zoneType.substr(2);
          if (format == "POINT")
          {
            this->GetUnstructuredGridFromPointPackingZone(
              numNodes, numElements, elType.c_str(), zoneIndex, ZoneName.c_str(), multZone);
          }
          else if (format == "BLOCK")
          {
            this->GetUnstructuredGridFromBlockPackingZone(
              numNodes, numElements, elType.c_str(), zoneIndex, ZoneName.c_str(), multZone);
          }
        }
        else if (zoneType == "FEPOLYHEDRON")
        {
          this->GetPolyhedralGridFromBlockPackingZone(
            numNodes, numElements, numFaces, zoneIndex, ZoneName.c_str(), multZone);
        }
        else if (zoneType == "FEPOLYGON")
        {
          this->GetPolygonalGridFromBlockPackingZone(
            numNodes, numElements, numFaces, zoneIndex, ZoneName.c_str(), multZone);
        }
        else
        {
          vtkWarningMacro(<< " ZONETYPE '" << zoneType << "' is currently unsupported.");
        }
      }

      zoneIndex++;
    }
    else if (tok == "DATASETAUXDATA")
    {
      int tokIndex = 0;
      bool haveVectorExpr = false;
      tok = this->Internal->GetNextToken();

      while (READ_UNTIL_LINE_END)
      {
        if (tokIndex == 0)
        {
          haveVectorExpr = (tok == "VECTOR");
        }
        else if (tokIndex == 1)
        {
          if (haveVectorExpr)
          {
            // Remove spaces
            std::string::size_type pos = tok.find(' ');
            while (pos != std::string::npos)
            {
              tok.replace(pos, 1, "");
              pos = tok.find(' ');
            }

            // Look for '('
            pos = tok.find('(');
            if (pos != std::string::npos)
            {
              std::string exprName(tok.substr(0, pos));
              std::string exprDef(tok.substr(pos, tok.size() - pos));

              exprDef.replace(0, 1, "{");

              // Replace ')' with '}'
              pos = exprDef.find(')');
              if (pos != std::string::npos)
              {
                exprDef.replace(pos, 1, "}");
                vtkDebugMacro("Expr name = " << exprName << ", Expr def = " << exprDef);
              }
            }
          }
        }

        // Skipping token
        tok = this->Internal->GetNextToken();
        tokIndex++;
      }

      tokenReady = true;
    }
    else if (firstToken && this->Internal->TokenIsString)
    {
      // Robust: assume it's a title
      this->DataTitle = tok;
    }
    else
    {
      // UNKNOWN RECORD TYPE
      vtkErrorMacro(<< this->FileName << ": The record type " << tok
                    << " found in the file is unknown.");
      return;
    }

    firstToken = false;
    if (!tokenReady)
    {
      tok = this->Internal->GetNextToken();
    }
  }
  this->Internal->ASCIIStream.close();

  if (this->Internal->TopologyDim > this->Internal->GeometryDim)
  {
    this->Internal->TopologyDim = this->Internal->GeometryDim;
  }

  this->Internal->Completed = 1;
}
VTK_ABI_NAMESPACE_END
